CN210639861U - Teaching is with automatic logistics production line - Google Patents

Abstract

The utility model relates to the field of automation equipment, and discloses an automatic logistics production line for teaching, which comprises a stereoscopic warehouse, a three-axis carrying robot, a first transport trolley, a material conveying belt device, an identification camera positioned above the material conveying belt device, a carrying robot in signal connection with the identification camera, an assembly conveying belt device, an assembly robot and a second transport trolley; the stereoscopic warehouse comprises a material storage area for storing materials to be assembled and processed and a finished product storage area for storing assembled finished products. The application provides a pair of automatic logistics production line is used in teaching sets up first travelling bogie through setting up between stereoscopic warehouse and material conveyer device, sets up the second travelling bogie between assembly conveyer device and stereoscopic warehouse, all sets up automatic unloading equipment of going up between every work area and working equipment to realized the full automated production of whole production line for teaching, improved automatic teaching level.

Description

Teaching is with automatic logistics production line

Technical Field

The utility model relates to an automation equipment field especially relates to a teaching is with automatic logistics production line.

Background

The logistics automation refers to the automation of equipment and facilities in the logistics operation process, and comprises the operation processes of transportation, loading and unloading, packaging, sorting, identification and the like. With the development of modern industrial automation technology, high-tech intelligent products such as industrial robots, AGV carrying trolleys, machine vision, intelligent stereoscopic warehouses and the like rise rapidly, and most enterprises urgently need high-tech automatic talents. The existing teaching instrument equipment for the automatic production line cannot realize full-automatic production teaching, the applied technology is old, students who participate in learning cannot well master the modern automation technology, cannot keep up with the steps of the development of modern science and technology, and the requirements of modern automation enterprises are difficult to meet.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an automatic logistics production line is used in teaching aims at solving the problem that automatic teaching instrument equipment still can't realize full automated production among the prior art.

In order to solve the technical problem, the utility model discloses a technical scheme be: the automatic logistics production line for teaching comprises a stereoscopic warehouse, a three-axis carrying robot, a first transport trolley, a material conveying belt device, an identification camera positioned above the material conveying belt device, a carrying robot in signal connection with the identification camera, an assembly conveying belt device, an assembly robot and a second transport trolley; the stereoscopic warehouse comprises a material storage area for storing materials to be assembled and processed and a finished product storage area for storing assembled finished products; the carrying robot comprises a second clamping jaw jig and a second vacuum chuck which are respectively used for carrying specific types of materials; the three-axis transfer robot transfers the different types of materials stored in the material storage area to the first transport trolley, the first transport trolley transports different types of materials to the material conveyor belt device, the identification camera takes pictures of the different types of materials on the material conveyor belt device for identification and transmits the identification result to the carrying robot, the carrying robot selects the second clamping jaw jig or the second vacuum chuck to carry the materials of specific types to the assembly conveyor belt device according to the identification result, the assembling robot assembles the materials on the assembling conveyor belt device into finished products and conveys the finished products to the second transport trolley, and the second transport trolley carries the finished products to the stereoscopic warehouse, and the three-axis carrying robot carries the finished products carried by the second transport trolley to the finished product storage area.

Further, a Y-axis guide rail is fixedly arranged on the three-axis carrying robot, a first sliding block is arranged on the Y-axis guide rail, a Z-axis moving guide rail fixedly connected with the first sliding block is arranged on the first sliding block, the Z-axis moving guide rail and the first sliding block move along the Y axis together, a second sliding block is arranged on the Z-axis guide rail, an X-axis moving guide rod fixedly connected with the second sliding block is arranged on the second sliding block, the X-axis moving guide rod and the second sliding block move along the Z axis together, a third sliding block is arranged on the X-axis moving guide rod, and a clamping mechanism used for carrying specific types of materials is arranged on the third sliding block.

Furthermore, a conveyor belt used for placing materials is arranged on the first transport trolley, the vertical height of the conveyor belt is consistent with that of the material conveyor belt device, the conveyor belt is in a static state in the process of conveying the materials from the stereoscopic warehouse to the material conveyor belt device, and when the first transport trolley drives the materials to move to abut against the material conveyor belt device, the conveyor belt starts to move and conveys the materials to the material conveyor belt device.

Furthermore, an electromagnetic track for the first transport trolley to run is arranged below the first transport trolley.

Further, the carrying robot controls the second clamping jaw jig through the clamping jaw air cylinder.

Further, the assembly robot comprises a third clamping jaw jig and a third vacuum chuck, wherein the third clamping jaw jig and the third vacuum chuck are respectively used for assembling and carrying specific types of materials, and the assembly robot adopts a clamping jaw cylinder to control the third clamping jaw jig.

Further, a transport box for placing finished products is arranged on the second transport trolley.

Furthermore, the first transport trolley and the second transport trolley both adopt AGV trolleys.

Compared with the prior art, the utility model discloses mainly there is following beneficial effect:

the utility model provides an automatic logistics production line for teaching, which is characterized in that a first transport trolley is arranged between a stereoscopic warehouse and a material conveyor belt device, a second transport trolley is arranged between an assembly conveyor belt device and the stereoscopic warehouse, a three-axis transfer robot is arranged between the stereoscopic warehouse and the first transport trolley and between the second transport trolley, a transfer robot is arranged between the material conveyor belt device and the assembly conveyor belt device, and an assembly robot is arranged between the assembly conveyor belt device and the second transport trolley; the material is conveyed to the first transport trolley from the material storage area of the stereoscopic warehouse by controlling the three-axis conveying robot, the material is conveyed to the material conveying belt device by the first transport trolley, the material is conveyed to the assembly conveying belt device by the conveying robot through the clamping jaw jig and the vacuum chuck, the material is assembled into a finished product by the assembly robot and conveyed to the second transport trolley, the finished product is conveyed to the stereoscopic warehouse by the second transport trolley and conveyed to the finished product storage area by the three-axis conveying robot, and the whole working process is completely finished by the industrial robot, so that the full-automatic production of the whole production line for teaching is realized, and the automatic teaching level is improved.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic view of an automatic logistics production line for teaching according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a three-axis transfer robot in an automated logistics production line for teaching according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a first transportation cart in an automated logistics production line for teaching according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a transfer robot in an automated logistics production line for teaching according to an embodiment of the present invention.

Reference numerals: 1-stereoscopic warehouse, 2-three-axis transfer robot, 3-first transport trolley, 4-material conveying belt device, 5-identification camera, 6-transfer robot, 7-assembly conveying belt device, 8-assembly robot, 9-second transport trolley, 21-Y-axis guide rail, 22-first slide block, 23-Z-axis moving guide rail, 24-second slide block, 25-X-axis moving guide rod, 26-third slide block, 31-conveying belt, 32-electromagnetic rail, 61-second clamping jaw jig, 62-second vacuum chuck and 91-transport box.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that if there are the terms "upper", "lower", "left", "right", etc. indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of the description, but it is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore the terms describing the positional relationship in the drawings are only for illustrative purposes and are not to be construed as limitations of the present patent, and those skilled in the art can understand the specific meanings of the terms according to specific situations.

The following describes the implementation of the present invention in detail with reference to specific embodiments.

Referring to fig. 1, fig. 1 is a schematic view of an automatic logistics production line for teaching according to an embodiment of the present invention; the automatic logistics production line for teaching provided by the embodiment comprises a stereoscopic warehouse 1, a three-axis carrying robot 2, a first transport trolley 3, a material conveying belt device 4, an identification camera 5 positioned above the material conveying belt device 4, a carrying robot 6 in signal connection with the identification camera 5, an assembly conveying belt device 7, an assembly robot 8 and a second transport trolley 9; the stereoscopic warehouse 1 comprises a material storage area for storing materials to be assembled and processed and a finished product storage area for storing assembled finished products; the transfer robot 6 comprises a second jaw jig 61 and a second vacuum chuck 62 for transferring specific types of materials respectively; the three-axis carrying robot 2 carries different types of materials stored in the material storage area to the first transport trolley 3, the first transport trolley 3 carries the different types of materials to the material conveyor belt device 4, the recognition camera 5 takes pictures of the different types of materials on the material conveyor belt device 4 for recognition and transmits the recognition result to the carrying robot 6, the carrying robot 6 selects the second clamping jaw jig 61 or the second vacuum chuck 62 to carry the specific types of materials to the assembly conveyor belt device 7 according to the recognition result, the assembly robot 8 assembles the materials on the assembly conveyor belt device 7 into finished products and carries the finished products to the second transport trolley 9, the second transport trolley 9 carries the finished products to the stereoscopic warehouse 1, and the three-axis carrying robot 2 carries the finished products carried by the second transport trolley 9 to the finished product storage area.

According to the automatic logistics production line for teaching, the first transport trolley 3 is arranged between the stereoscopic warehouse 1 and the material conveyor belt device 4, the second transport trolley 9 is arranged between the assembly conveyor belt device 4 and the stereoscopic warehouse 1, the three-axis transfer robot 2 is arranged between the stereoscopic warehouse 1 and the first transport trolley 3 and between the second transport trolley 9, the transfer robot 6 is arranged between the material conveyor belt device 4 and the assembly conveyor belt device 7, and the assembly robot 8 is arranged between the assembly conveyor belt device 7 and the second transport trolley 9; the three-axis transfer robot 2 is controlled to transfer materials from a material storage area of the stereoscopic warehouse 1 to the first transport trolley 3, the first transport trolley 3 transfers the materials to the material conveyor belt device 4, the transfer robot 6 transfers the materials to the assembly conveyor belt device by using a clamping jaw jig and a vacuum chuck, the assembly robot 8 assembles the materials into finished products and transfers the finished products to the second transport trolley 9, the second transport trolley 9 transfers the finished products to the stereoscopic warehouse 1 and transfers the finished products to a finished product storage area by the three-axis transfer robot 2, and the whole working process is completely finished by the industrial robot, so that the full-automatic production of the whole production line for teaching is realized, and the automatic teaching level is improved.

Referring to fig. 2, specifically, a Y-axis guide rail 21 is fixedly arranged on the three-axis transfer robot, a first slider 22 is arranged on the Y-axis guide rail 21, a Z-axis moving guide rail 23 fixedly connected with the first slider 22 is arranged on the first slider 22, the Z-axis moving guide rail 23 and the first slider 22 move along the Y-axis together, a second slider 24 is arranged on the Z-axis moving guide rail 23, an X-axis moving guide rod 25 fixedly connected with the second slider 24 is arranged on the second slider 24, the X-axis moving guide rod 25 and the second slider 24 move along the Z-axis together, a third slider 26 is arranged on the X-axis moving guide rod 25, and a clamping mechanism for carrying a specific type of material is arranged on the third slider 26; in some embodiments, the gripping mechanism comprises a jaw cylinder, a first jaw fixture connected to the jaw cylinder, and a first vacuum chuck; after first clamping jaw tool and first vacuum chuck obtain the material in stereoscopic warehouse 1 or after obtaining the finished product on second travelling bogie 9, can move in X axle direction along X axle removal guide arm 25, simultaneously, X axle removal guide arm 25 can drive first clamping jaw tool and first vacuum chuck and remove in Z axle direction, and moreover, Z axle removal guide rail 23 can drive X axle removal guide arm 25 and remove in Y axle direction, thereby realized the all-round cover to stereoscopic warehouse 1 internal position.

Referring to fig. 1 and fig. 3, specifically, a conveyor belt 31 for placing the material is disposed on the first transport trolley 3, a vertical height of the conveyor belt 31 is consistent with that of the material conveyor belt device 4, the conveyor belt is in a static state during the material is conveyed from the stereoscopic warehouse 1 to the material conveyor belt device 4, and when the first transport trolley 3 drives the material to move to abut against the material conveyor belt device 4, the conveyor belt 31 starts to move and conveys the material onto the material conveyor belt device 4.

Specifically, the electromagnetic rail 32 that supplies first travelling bogie 3 to travel is arranged below first travelling bogie 3, and the route of marcing of first travelling bogie 3 is established to utilize electromagnetic rail 32, can guarantee that the operation of first travelling bogie 3 is stable, and first travelling bogie 3 needs make a round trip movement between stereoscopic warehouse 1 and material conveyor belt device 4 simultaneously, and work efficiency and production safety can be guaranteed to stable route of marcing.

Specifically, a transport box 91 for placing finished products is arranged on the second transport trolley 9, and in the process that the finished products are conveyed to the stereoscopic warehouse 1 from the assembly conveyor belt device 7 by the second transport trolley 9, the transport box 91 can ensure the safety of the finished products in the transportation process and prevent the finished products from falling off to cause unnecessary loss.

Preferably, the first transport trolley 3 and the second transport trolley 9 both adopt AGV trolleys, the AGV trolleys adopt electromagnetic automatic guiding devices, can run along a specified guiding path, do not need a driver, and provide power sources for the AGV trolleys by rechargeable storage batteries, so that the AGV trolleys are very convenient.

Referring to fig. 1 and 4, specifically, the transfer robot 6 controls the second jaw jig 61 through the jaw cylinder; when the recognition camera 5 transmits the recognition result of the material to the transfer robot 6, the transfer robot 6 can control the second clamping jaw jig 61 through the clamping jaw cylinder, clamp the material of a specific type on the material conveyor belt device 4 and transfer the material onto the assembly conveyor belt device 7, and meanwhile, the transfer robot 6 can also control the second vacuum chuck 62 to suck the material of the specific type on the material conveyor belt device 4 and transfer the material onto the assembly conveyor belt device 7.

Specifically, the assembly robot 8 comprises a third clamping jaw jig and a third vacuum chuck which are respectively used for assembling and carrying specific types of materials, and the assembly robot 8 adopts a clamping jaw cylinder to control the third clamping jaw jig; after the material is conveyed to the upper surface of the assembly conveyor belt device 7 by the conveying robot 8, the assembly robot 8 can clamp the material of the specific type on the assembly conveyor belt device 7 by controlling the third clamping jaw jig controlled by the clamping jaw cylinder, meanwhile, the assembly robot 8 can suck the material of the specific type on the assembly conveyor belt device 7 by controlling the third vacuum chuck and assemble the sucked material of the specific type and the material of the specific type clamped by the third clamping jaw jig together, and after the assembly is completed, the third clamping jaw jig conveys the assembled finished product to the second transport trolley 9.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing detailed description, or equivalent replacements may be made for some of the technical features of the embodiments. All utilize the equivalent structure that the content of the utility model discloses a specification and attached drawing was done, direct or indirect application is in other relevant technical field, all is in the same way the utility model discloses within the patent protection scope.

Claims (8)

1. An automatic logistics production line for teaching is characterized by comprising a stereoscopic warehouse, a three-axis carrying robot, a first transport trolley, a material conveying belt device, an identification camera positioned above the material conveying belt device, a carrying robot in signal connection with the identification camera, an assembly conveying belt device, an assembly robot and a second transport trolley; the stereoscopic warehouse comprises a material storage area for storing materials to be assembled and processed and a finished product storage area for storing assembled finished products; the carrying robot comprises a second clamping jaw jig and a second vacuum chuck which are respectively used for carrying specific types of materials; the three-axis transfer robot transfers the different types of materials stored in the material storage area to the first transport trolley, the first transport trolley transports different types of materials to the material conveyor belt device, the identification camera takes pictures of the different types of materials on the material conveyor belt device for identification and transmits the identification result to the carrying robot, the carrying robot selects the second clamping jaw jig or the second vacuum chuck to carry the materials of specific types to the assembly conveyor belt device according to the identification result, the assembling robot assembles the materials on the assembling conveyor belt device into finished products and conveys the finished products to the second transport trolley, and the second transport trolley carries the finished products to the stereoscopic warehouse, and the three-axis carrying robot carries the finished products carried by the second transport trolley to the finished product storage area.

2. The automated logistics production line for teaching of claim 1, wherein a Y-axis guide rail is fixedly arranged on the three-axis transfer robot, a first slider is arranged on the Y-axis guide rail, a Z-axis moving guide rail fixedly connected with the first slider is arranged on the first slider, the Z-axis moving guide rail and the first slider move along the Y-axis together, a second slider is arranged on the Z-axis guide rail, an X-axis moving guide rod fixedly connected with the second slider is arranged on the second slider, the X-axis moving guide rod and the second slider move along the Z-axis together, a third slider is arranged on the X-axis moving guide rod, and a clamping mechanism for carrying a specific type of material is arranged on the third slider.

3. The automated material flow production line for teaching of claim 1, wherein a conveyor belt for placing materials is arranged above the first transport trolley, the vertical height of the conveyor belt is consistent with that of the material conveyor belt device, the conveyor belt is in a static state in the process of conveying the materials from the stereoscopic warehouse to the material conveyor belt device, and when the first transport trolley drives the materials to move to abut against the material conveyor belt device, the conveyor belt starts to move and conveys the materials to the material conveyor belt device.

4. The automated logistics production line for teaching of claim 1, wherein an electromagnetic track for the first transport vehicle to travel is arranged below the first transport vehicle.

5. The automated logistics production line for teaching of claim 1, wherein the transfer robot controls the second jaw jig through a jaw cylinder.

6. The automated logistics production line for teaching of claim 1, wherein the assembly robot comprises a third clamping jaw fixture and a third vacuum chuck for assembling and carrying specific types of materials respectively, and the assembly robot controls the third clamping jaw fixture by adopting a clamping jaw cylinder.

7. The automated logistics production line for teaching of claim 1, wherein a transport box for placing finished products is arranged above the second transport trolley.

8. The automated logistics production line of any one of claims 1 to 7, wherein the first transport vehicle and the second transport vehicle are AGV vehicles.

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